Deletion of the membrane anchoring region of tissue factor abolishes autoactivation of factor VII but not cofactor function. Analysis of a mutant with a selective deficiency in activity.

The activation of human blood coagulation factor VII can occur by the feedback activity of either factor VIIa (autoactivation) or factor Xa. Both of these reactions are known to be enhanced by the presence of tissue factor, an integral membrane protein and the cofactor for factor VIIa. We examine here the activation of 125I-factor VII by both factor VIIa and factor Xa employing a mutant soluble form of tissue factor which has had its transmembrane and cytoplasmic domains deleted (sTF1-219). This mutant soluble tissue factor retains cofactor activity toward factor VIIa in a single-stage clotting assay but shows a strong dependence on initial plasma levels of factor VIIa (from 1 to 10,000 ng/ml) when compared to wild-type tissue factor. We show that this dependence is due to a deficiency of sTF1-219 in ability to both promote autoactivation and enhance the factor Xa-catalyzed activation of 125I-factor VII. sTF1-219 does not, however, inhibit the tissue factor-independent activation of 125I-factor VII by factor Xa. The results strongly suggest that the phospholipid anchoring region of tissue factor is essential for autoactivation and beneficial for factor Xa-catalyzed activation of 125I-factor VII. In addition, when taken together with the dependence of clotting times on initial factor VIIa levels observed with sTF1-219, these results indicate that factor VII autoactivation may be of greater importance in the initiation of blood coagulation via tissue factor than has been previously realized.     

Tissue factor residues 157-167 are required for efficient proteolytic activation of factor X and factor VII.

The cell surface receptor tissue factor (TF) initiates coagulation by supporting the proteolytic activation of factors X and IX as well as VII to active serine proteases. Architectural similarity of TF to the cytokine receptor family suggests a strand-loop-strand structure for TF residues 151-174. Site-directed Ala exchanges in the predicted surface loop demonstrated that residues Tyr157, Lys159, Ser163, Gly164, Lys165, and Lys166 are important for function. Addition of side chain atoms at the Ser162 position decreased function, whereas the Ala exchange was tolerated. The dysfunctional mutants bound VII with high affinity and fully supported the catalysis of small peptidyl substrates by the mutant TF.VIIa complex. Lys159-->Ala substitution was compatible with efficient activation of factor X, whereas the Try157-->Ala exchange and mutations in the carboxyl aspect of the predicted loop resulted in diminished activation of factor X. The specific plasma procoagulant activity of all functionally deficient mutants increased 7- to 200-fold upon the supplementation of VIIa suggesting that TF residues 157-167 also provide important interactions that accelerate the activation of VII to VIIa. These data are consistent with assignment of the TF 157-167 region as contributing to protein substrate recognition and cleavage by the TF.VIIa complex.     

The tissue factor region that interacts with substrates factor IX and Factor X

The enzymatic activity of coagulation factor VIIa is controlled by its cellular cofactor tissue factor (TF). TF binds factor VIIa with high affinity and, in addition, participates in substrate interaction through its C-terminal fibronectin type III domain. We analyzed surface-exposed residues in the C-terminal TF domain to more fully determine the area on TF important for substrate activation. Soluble TF (sTF) mutants were expressed in E. coli, and their ability to support factor VIIa-dependent substrate activation was measured in the presence of phospholipid vesicles or SW-13 cell membranes. The results showed that factor IX and factor X interacted with the same TF region located proximal to the putative phospholipid surface. According to the degree of activity loss of the sTF mutants, this TF region can be divided into a main region (residues Tyr157, Lys159, Ser163, Gly164, Lys165, Lys166, Tyr185) forming a solvent-exposed patch of 488 A(2) and an extended region which comprises an additional 7-8 residues, including the distally positioned Asn199, Arg200, and Asp204. Some of the identified TF residues, such as Trp158 and those within the loop Lys159-Lys165, are near the factor VIIa gamma-carboxyglutamic acid (Gla) domain, suggesting that the factor VIIa Gla-domain may also participate in substrate interaction. Moreover, the surface identified as important for substrate interaction carries a net positive charge, suggesting that charge interactions may significantly contribute to TF-substrate binding. The calculated surface-exposed area of this substrate interaction region is about 1100 A(2), which is approximately half the size of the TF area that is in contact with factor VIIa. Therefore, a substantial portion of the TF surface (3000 A(2)) is engaged in protein-protein interactions during substrate catalysis.     

The first epidermal growth factor domain of human coagulation factor VII is essential for binding with tissue factor.

The intrinsic pathway of coagulation is initiated when zymogen factor VII binds to its cell surface receptor tissue factor to form a catalytic binary complex. Both the activation of factor VIIa and the expression of serine protease activity of factor VIIa are dependent on factor VII binding to tissue factor lipoprotein. To better understand the molecular basis of these rate-limiting events, the interaction of zymogen factor VII and tissue factor was investigated using as probes both a murine monoclonal antibody and a monospecific rabbit antiserum to human factor VII. To measure factor VIIa functional activity, a two-stage chromogenic assay was used; an assay which measures the factor Xa generated by the activation of factor VII to factor VIIa. Purified immunoglobulin from murine monoclonal antibody 231-7, which was shown to be reactive with amino acid residues 51-88 of the first epidermal growth factor-like (EGF) domain of human factor VII, inhibited the activation of factor VII to factor VIIa in a dose-dependent manner. The mechanism of this inhibition was demonstrated using a novel solid-phase ELISA which quantitatively measured the binding of purified factor VII zymogen to tissue factor adsorbed onto microtiter wells. Thus, the binding of factor VII zymogen to immobilized tissue factor was inhibited by antibody 231-7, again in a dose-dependent manner. Similar results were obtained using a monospecific rabbit antiserum to human factor VII which also reacted with the beta-galactosidase fusion proteins containing amino acid residues 51-88 (exon 4) of human factor VII. We conclude therefore that the exon 4-encoded amino acids of the first EGF domain of human factor VII constitute an essential domain participating in the binding of factor VII to tissue factor.     

Raising the active site of factor VIIa above the membrane surface reduces its procoagulant activity but not factor VII autoactivation

Tissue factor, the physiologic trigger of blood clotting, is the membrane-anchored protein cofactor for the plasma serine protease, factor VIIa. Tissue factor is hypothesized to position and align the active site of factor VIIa relative to the membrane surface for optimum proteolytic attack on the scissile bonds of membrane-bound protein substrates such as factor X. We tested this hypothesis by raising the factor VIIa binding site above the membrane surface by creating chimeras containing the tissue factor ectodomain linked to varying portions of the membrane-anchored protein, P-selectin. The tissue factor/P-selectin chimeras bound factor VIIa with high affinity and supported full allosteric activation of factor VIIa toward tripeptidyl-amide substrates. That the active site of factor VIIa was raised above the membrane surface when bound to tissue factor/P-selectin chimeras was confirmed using resonance energy transfer techniques in which appropriate fluorescent dyes were placed in the active site of factor VIIa and at the membrane surface. The chimeras were deficient in supporting factor X activation by factor VIIa due to decreased k(cat). The chimeras were also markedly deficient in clotting plasma, although incubating factor VII or VIIa with the chimeras prior to the addition of plasma restored much of their procoagulant activity. Interestingly, all chimeras fully supported tissue factor-dependent factor VII autoactivation. These studies indicate that proper positioning of the factor VII/VIIa binding site on tissue factor above the membrane surface is important for efficient rates of activation of factor X by this membrane-bound enzyme/cofactor complex.     

Binding of human factors VII and VIIa to a human bladder carcinoma cell line (J82). Implications for the initiation of the extrinsic pathway of blood coagulation

We have studied the binding of radioiodinated human factor VII and its activated form, factor VIIa, to monolayers of a human bladder carcinoma cell line (J82) that expresses functional cell surface tissue factor. The binding of factors VII and VIIa to these cells was found to be time-, temperature-, and calcium-dependent. In addition, the binding of each protein to J82 cells was specific, dose-dependent, and saturable. The binding isotherms for factors VII and VIIa were hyperbolic, and Scatchard plots of the binding data obtained at 37 degrees C indicated a single class of binding sites for each protein with Kd values of 3.20 +/- 0.51 and 3.25 +/- 0.31 nM, respectively. Factors VII and VIIa, respectively, interacted with 256,000 +/- 39,000 and 320,000 +/- 31,000 binding sites/cell. Competition experiments suggested a common receptor for factors VII and VIIa. Binding of factor VIIa to the cells was completely blocked by preincubation of the cells with polyclonal anti-tissue factor IgG, whereas binding of factor VII was inhibited approximately 90%, suggesting the presence of a small number of tissue factor-independent binding sites specific for factor VII on this cell. Functional studies revealed that factor X activation by increasing amounts of cell-bound factor VII or VIIa was hyperbolic in nature. Half-maximal rates of factor Xa formation occurred at factor VII and VIIa concentrations of 3.7 +/- 0.47 and 3.2 +/- 0.31 nM, respectively. No factor VII- or VIIa-mediated activation of factor X was observed when cells were preincubated with anti-tissue factor IgG. Two-chain 125I-factor VIIa recovered from the cells was identical to the offered ligand as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. In contrast, the offered single-chain 125I-factor VII was progressively converted to two-chain 125I-factor VIIa upon binding to the cells. When the J82 cells were pretreated with anti-tissue factor IgG, both factor VII recovered from the cells and factor VII in the supernatant were in the single-chain form, indicating that cell-surface tissue factor was essential for the activation of factor VII on these cells. These data indicate that binding of factor VII to tissue factor appears to be a prerequisite for its conversion to factor VIIa and the initiation of the extrinsic pathway of coagulation on these cells.     

Initiation of the extrinsic pathway of blood coagulation: evidence for the tissue factor dependent autoactivation of human coagulation factor VII

Previous studies demonstrated proteolytic activation of human blood coagulation factor VII by an unidentified protease following complex formation with tissue factor expressed on the surface of a human bladder carcinoma cell line (J82). In the present study, an active-site mutant human factor VII cDNA (Ser344----Ala) has been constructed, subcloned, and expressed in baby hamster kidney cells. Mutant factor VII was purified to homogeneity in a single step from serum-free culture supernatants by immunoaffinity column chromatography. Mutant factor VII was fully carboxylated, possessed no apparent clotting activity, and was indistinguishable from plasma factor VII by SDS-PAGE. Cell binding studies indicated that mutant factor VII bound to J82 tissue factor with essentially the same affinity as plasma factor VII and was cleaved by factor Xa at the same rate as plasma factor VII. In contrast to radiolabeled single-chain plasma factor VII that was progressively converted to two-chain factor VIIa on J82 monolayers, mutant factor VII was not cleaved following complex formation with J82 tissue factor. Incubation of radiolabeled mutant factor VII with J82 cells in the presence of recombinant factor VIIa resulted in the time-dependent and tissue factor dependent conversion of single-chain mutant factor VII to two-chain mutant factor VIIa. Plasma levels of antithrombin III had no discernible effect on the factor VIIa catalyzed activation of factor VII on J82 cell-surface tissue factor but completely blocked this reaction catalyzed by factor Xa. These results are consistent with an autocatalytic mechanism of factor VII activation following complex formation with cell-surface tissue factor, which may play an important role in the initiation of extrinsic coagulation in normal hemostasis.     

Identification of molecular sites on factor VII which mediate its assembly and function in the extrinsic pathway activation complex

Factor VII-VIIa, in association with tissue factor, participates in the complex which initiates blood coagulation through the extrinsic pathway. To identify functional domains on factor VII which mediate the activation of factor X, 16 synthetic peptides corresponding to 55% of the primary structure were assayed for their ability to inhibit factor VII function. Factor Xa formation was inhibited by eight of the peptides in a dose-dependent manner. Kinetic analyses indicated noncompetitive inhibition of factor X activation by seven of these peptides. Peptide-(347-361) inhibited factor Xa cleavage of a chromogenic substrate by a competitive mechanism and was excluded from further analysis in this study. Among the seven inhibitory peptides which have the ability to prevent the factor VIIa-tissue factor-mediated conversion of factor X to factor Xa, peptide-(285-305) was most inhibitory, with a Ki value of 2.4 microM. The Ki values were in the range of 42-65 microM for peptides-(44-50), -(194-214), -(208-229), and -(376-390). The least inhibitory peptides were at positions 170-178 and 330-340, with a Ki value greater than 200 microM. Polyclonal antibodies were raised against four of these peptides; and when antisera were assayed by a solid-phase radioimmunoassay, they bound not only to their respective immunizing peptides, but also to factor VII. The Fab fragments of specific IgG preparations, affinity-purified on a factor VII-agarose column, inhibited the rate of factor X activation in a dose-dependent manner. Six of the seven inhibitory peptides represent amino acid sequences within the heavy chain of factor VII, and the remaining one corresponds to a sequence within the light chain. The corresponding regions in the x-ray crystal structure of chymotrypsin represented by the six heavy chain inhibitory peptides are found to be located in three distinct regions, one region located spatially distal to the active site and the other two regions located relatively closer to the active site and the substrate-binding pocket. The results suggest that at least three specific regions in the heavy chain and one region in the light chain of factor VII mediate its interaction with the factor X activation complex.     

Tissue factor-dependent autoactivation of human blood coagulation factor VII.

We recently showed that single-chain zymogen factor VII is converted to two-chain factor VIIa in an autocatalytic manner following complex formation with either cell-surface or solution-phase relipidated tissue factor apoprotein (Nakagaki, T., Foster, D. C., Berkner, K. L., and Kisiel, W. (1991) Biochemistry 30, 10819-10824). We have now performed a detailed kinetic analysis of the autoactivation of human plasma factor VII in the presence of relipidated recombinant tissue factor apoprotein and calcium. Incubation of factor VII with equimolar amounts of relipidated tissue factor apoprotein resulted in the formation of factor VIIa amidolytic activity coincident with the conversion of factor VII to factor VIIa. The time course for the generation of factor VIIa amidolytic activity in this system was sigmoidal, characterized by an initial lag phase followed by a rapid linear phase until activation was complete. The duration of the lag phase was decreased by the addition of exogenous recombinant factor VIIa. Relipidated tissue factor apoprotein was essential for factor VII autoactivation. No factor VII activation was observed following complex formation between factor VII and a recombinant soluble tissue factor apoprotein construct consisting of the aminoterminal extracellular domain in the presence or absence of phospholipids. Kinetic analyses revealed that factor VII activation in the presence of relipidated tissue factor apoprotein can be defined by a second-order reaction mechanism in which factor VII is activated by factor VIIa with an apparent second-order rate constant of 7.2 x 10(3) M-1 S-1. Benzamidine inhibited factor VII autoactivation with an apparent Ki of 1.8 mM, which is identical to the apparent Ki for the inhibition of factor VIIa amidolytic activity by this active site competitive inhibitor. Our data are consistent with a factor VII autoactivation mechanism in which trace amounts of factor VIIa rapidly activate tissue factor-bound factor VII by limited proteolysis.     

Cooperative interaction between factor VII and cell surface-expressed tissue factor

Assembly of the extrinsic pathway on cell surfaces was investigated by studying the binding and activity of factor VII on the bladder carcinoma cell line J82 which expressed 18,800 milliunits of tissue factor activity/10(6) cells. In binding studies, the association of factor VII to monolayers of cells was time-, temperature-, and calcium-dependent. The ligand binding was specific, reversible, and saturable. This interaction was inhibited by a monoclonal antibody to human brain tissue factor. Factor VII added to the cells was recovered as factor VII rather than factor VIIa when incubated in the presence of factor X neutralizing antibodies, suggesting that these cells produced factor X. Specific factor VII binding to the cell revealed a sigmoidal binding isotherm with half-maximal binding occurring at 314 +/- 145 pM to 38,300 +/- 14,300 sites/cell. Hill plots of the binding data indicated an average slope of 2.1. Binding parameters were also determined kinetically. At maximal factor VII-tissue factor complex formation the apparent Km for factor X was 274 nM, the Vmax was 4.15 nM/min, and the kcat was estimated to be 14 s-1. In the presence of excess tissue factor and factor X, increasing amounts of factor VII added to the J82 cells demonstrated a sigmoidal relationship with the rate of factor Xa formation. Hill plots indicated a slope of 2.0 at the lower factor VII concentrations which changed to 1.0 at the higher input amounts of factor VII. Hanes plots were used to determine the apparent dissociation constant of the interaction (222 +/- 85 pM). The Vmax was 5.54 +/- 1.04 nM/min for the cleavage of factor X. These data are consistent with factor VII binding to at least two sites on tissue factor (receptor) with positive cooperativity. Because at saturation the stoichiometry of the factor VII-tissue factor complex is 1:1, tissue factor must be expressed as a dimer on the surface of the J82 cells.     

Crystal structures of uninhibited factor VIIa link its cofactor and substrate-assisted activation to specific interactions

Factor VIIa initiates the extrinsic coagulation cascade; this event requires a delicately balanced regulation that is implemented on different levels, including a sophisticated multi-step activation mechanism of factor VII. Its central role in hemostasis and thrombosis makes factor VIIa a key target of pharmaceutical research. We succeeded, for the first time, in recombinantly producing N-terminally truncated factor VII (rf7) in an Escherichia coli expression system by employing an oxidative, in vitro, folding protocol, which depends critically on the presence of ethylene glycol. Activated recombinant factor VIIa (rf7a) was crystallised in the presence of the reversible S1-site inhibitor benzamidine. Comparison of this 1.69A crystal structure with that of an inhibitor-free and sulphate-free, but isomorphous crystal form identified structural details of factor VIIa stimulation. The stabilisation of Asp189-Ser190 by benzamidine and the capping of the intermediate helix by a sulphate ion appear to be sufficient to mimic the disorder-order transition conferred by the cofactor tissue factor (TF) and the substrate factor X. Factor VIIa shares with the homologous factor IXa, but not factor Xa, a bell-shaped activity modulation dependent on ethylene glycol. The ethylene glycol-binding site of rf7a was identified in the vicinity of the 60 loop. Ethylene glycol binding induces a significant conformational rearrangement of the 60 loop. This region serves as a recognition site of the physiologic substrate, factor X, which is common to both factor VIIa and factor IXa. These results provide a mechanistic framework of substrate-assisted catalysis of both factor VIIa and factor IXa.     

Characterization of factor VII association with tissue factor in solution. High and low affinity calcium binding sites in factor VII contribute to functionally distinct interactions

Protein-phospholipid as well as protein-protein interactions may be critical for tight binding of the serine protease factor VIIa (VIIa) to its receptor cofactor tissue factor (TF). To elucidate the role of protein-protein interactions, we analyzed the interaction of VII/VIIa with TF in the absence of phospholipid. Binding of VII occurred with similar affinity to solubilized and phospholipid-reconstituted TF. Lack of the gamma-carboxyglutamic acid (Gla)-domain (des-(1-38)-VIIa) resulted in a 10- to 30-fold increase of the Kd for the interaction, as did blocking the Gla-domain by Fab fragments of a specific monoclonal antibody. These results suggest that the VII Gla-domain can participate in protein-protein interaction with the TF molecule per se rather than only in interactions with the charged phospholipid surface. Gla-domain-independent, low affinity binding of VII to TF required micromolar Ca2+, indicating involvement of high affinity calcium ion binding sites suggested to be localized in VII rather than TF. Interference with Gla-domain-dependent interactions with TF did not alter the TF. VIIa-dependent cleavage of a small peptidyl substrate, whereas the proteolytic activation of the protein substrate factor X was markedly decreased, suggesting that the VIIa Gla-domain not only participates in the formation of a more stable TF. VIIa complex but contributes to extended substrate recognition.     

Autoactivation of human recombinant coagulation factor VII

Single-chain human recombinant factor VII produced by transfected baby hamster kidney cells was purified to homogeneity in the presence of benzamidine. The amidolytic activity of single-chain recombinant factor VII with a peptidylnitroanilide substrate, methoxycarbonyl-D-cyclohexanylglycyl-L-arginine-p-nitroanilide, was less than 1% of that obtained with factor VIIa. Purified single-chain recombinant factor VII spontaneously activated in the absence of inhibitor. The activation reaction was enhanced by at least 2 orders of magnitude in the presence of a positively charged surface, provided either as an anion-exchange matrix or as poly(D-lysine). The progress curve for factor VIIa generation was sigmoidal. Benzamidine inhibits recombinant factor VIIa activity and factor VII activation with identical inhibition constants (Ki) of 11 mM. In contrast, benzamidine inhibition of bovine factor Xa and bovine factor IIa was observed at Ki values equal to 0.3 and 0.5 mM, respectively. Bovine factors Xa and IIa are known activators of factor VII and the most likely contaminants of our recombinant factor VII preparations. Single-chain recombinant factor VII purified from cells cultured in the absence of bovine serum activated at the same rate as factor VII from cells cultured in the presence of bovine serum. This also excluded the possibility that the activation reaction was caused by contaminating bovine proteases. On the basis of these observations, we propose that factor VII is autoactivated in vitro in the presence of a positively charged surface.     

Tissue factor is not involved in the mitogenic activity of factor VIIa

The present study was undertaken to evaluate in vitro the importance of tissue factor in the mitogenic effect of factor VIIa for embryonic fibroblasts. For that purpose, embryonic fibroblasts were isolated from either wild-type or transgenic mice showing a single inactivation of the tissue factor gene or expressing a truncated form (lacking the cytosolic domain) of this protein. Factor VIIa stimulated in a dose-dependent manner the growth of the 3 types of fibroblasts, thus showing that TF is not involved in the mitogenic activity of factor VIIa. The mitogenic activity of factor VIIa disappeared in serum immunopurified in factor X and was almost totally inhibited by DX9065, a selective factor Xa inhibitor, showing that this effect of factor VIIa occurred via factor Xa generated during the incubation period. Hirudin did not show any significant effect on factor VIIa-induced fibroblast proliferation, thus showing that the effect observed for factor VIIa was selectively mediated by factor Xa and was not due to thrombin formation. Our results therefore represent the first evidence for the possible importance of factor Xa in the mitogenic effect of factor VIIa and show the negligible role of tissue factor in this process.     

Formation of factors IXa and Xa by the extrinsic pathway: differential regulation by tissue factor pathway inhibitor and antithrombin III

The activation of factor X by VIIa/TF and the Xa-dependent inhibition of the enzyme complex by tissue factor pathway inhibitor (TFPI) are considered primary steps in the initiation of coagulation. IX activation by VIIa/TF is considered to contribute catalyst necessary for further Xa production in the ensuing amplification phase. We have investigated Xa and IXabeta production by VIIa-TF in a system reconstituted with both X and IX and the principal physiologic inhibitors of this pathway TFPI and antithrombin III (AT). Kinetic studies without inhibitors established that IX and X functioned as competitive alternate substrates for VIIa/TF with similar kinetic constants. When both IX and X were present, TFPI significantly inhibited the extent of formation of either IXabeta or Xa. In contrast, AT rapidly depleted active Xa with a small effect on IXabeta formation. When both AT and TFPI were present, active IXabeta formation significantly exceeded the formation of active Xa regardless of the VIIa/TF concentration. These findings could be quantitatively accounted for by a model encompassing the kinetics of the individual activation and inhibition steps. Active Xa formation by this pathway is regulated in a principal way by its rapid inactivation by AT. In contrast, the Xa-dependent inhibitory reactions of TFPI play a primary role in limiting zymogen consumption and the formation of active IXabeta. These regulatory phenomena yield active IXabeta as a major rather than secondary product of VIIa/TF. Our findings raise the possibility that IXabeta produced by the extrinsic pathway, and its ability to function within the intrinsic Xase complex to activate X may play a significant role in producing Xa necessary for both the initiation and sustained phases of the procoagulant response following vascular damage.     

Residues Y179 and H101 of a hydrophobic patch of factor VII are involved in activation by factor Xa

We studied factor Xa activation of human factor VII in hopes of identifying factor VII residues, not adjacent to the cleavage site, involved in this interaction. We made eight factor VIIs with single mutations (N100A, H101A, D102Q, L144A, R147A, Y179A, D186A, and F256A) and two factor VIIs with multiple mutations [MM3 (L144A/R147A/D186A) and MM4 (N100A/H101A/Y179A/F256A)]. Residues in MM3 have previously been identified as affecting factor X activation, and the residues of MM4 are located at a hydrophobic patch of factor VII on the opposite side of the catalytic domain from those in MM3. Only H101A, Y179A, and MM4 were activated significantly more slowly than the wild type. Results of our kinetic analyses showed that the catalytic efficiency of factor Xa for activation of factor VII was 176- and 234-fold higher than that for H101A andY179A, respectively. All the mutants with measurable activity had affinities for tissue factor similar to those of the wild type. The activated hydrophobic patch residues, except N100A, which is adjacent to one of the catalytic residues, had normal activities toward both a small peptide substrate and factor X. The rest of the activated mutants (except D102Q with no activity) had reduced activities toward the small substrate (except R147A) and factor X. We conclude that factor VII activation by factor Xa and factor VIIa's catalytic interaction with factor X involve different regions in the catalytic domain, and residues H101 and Y179, part of an aromatic hydrophobic patch, are specifically involved in factor Xa activation of factor VII.     

Molecular recognition in the activation of human blood coagulation factor X

Factor X can be activated by the extrinsic activation complex (factor VIIa:tissue factor), the intrinsic activation complex (factor IXa:factor VIIIa) and by an enzyme from Russell's viper venom (RVV-X). To identify the regions on the surface of factor X that mediate its association with these three activators, we have prepared 21 synthetic peptides representing 65% of the primary structure of factor X. Only 3 of the 21 peptides inhibited the rate of factor X activation, indicating the regions represented by these three peptides are involved in factor X association. Using purified components, the rate of factor Xa formation was inhibited in a dose-dependent manner by these three peptides with the same relative potency of inhibition in each of the activation systems. The observed relative potencies were: peptide 267-283 greater than or equal to peptide 284-303 greater than peptide 417-431. Kinetic analyses indicated that the three peptides inhibited factor X activation in a non-competitive manner, and in mixed inhibitor assays the peptides were shown to be mutually exclusive of one another. In coagulation-based assays, the potency of inhibition by each peptide was decreased. However, in Russell's viper venom-X-initiated assays peptide 417-431 was the best inhibitor. Fab fragments of antibodies raised to these peptides and affinity purified on factor X-agarose columns inhibited both the purified and coagulation-based assays in a dose-dependent manner. Using the x-ray crystal structure of chymotrypsinogen as a model, these three peptides were found to be located spatially close to one another on the surface of factor X and opposite to the region where factor X is cleaved for activation. These data are consistent with a model in which the three activators combine with factor X through a recognition site composed of multiple loci that is distal to the potential cleavage site. This interaction aligns the active sites of these three enzymes in the correct orientation to cleave factor X at the same arginyl-isoleucyl bond.     

The contribution of amino acid region ASP695-TYR698 of factor V to procofactor activation and factor Va function

There is strong evidence that a functionally important cluster of amino acids is located on the COOH-terminal portion of the heavy chain of factor Va, between amino acid residues 680 and 709. To ascertain the importance of this region for cofactor activity, we have synthesized five overlapping peptides representing this amino acid stretch (10 amino acids each, HC1-HC5) and tested them for inhibition of prothrombinase assembly and function. Two peptides, HC3 (spanning amino acid region 690-699) and HC4 (containing amino acid residues 695-704), were found to be potent inhibitors of prothrombinase activity with IC(50) values of approximately 12 and approximately 10 microm, respectively. The two peptides were unable to interfere with the binding of factor Va to active site fluorescently labeled Glu-Gly-Arg human factor Xa, and kinetic analyses showed that HC3 and HC4 are competitive inhibitors of prothrombinase with respect to prothrombin with K(i) values of approximately 6.3 and approximately 5.3 microm, respectively. These data suggest that the peptides inhibit prothrombinase because they interfere with the incorporation of prothrombin into prothrombinase. The shared amino acid motif between HC3 and HC4 is composed of Asp(695)-Tyr-Asp-Tyr-Gln(699) (DYDYQ). A pentapeptide with this sequence inhibited both prothrombinase function with an IC(50) of 1.6 microm (with a K(D) for prothrombin of 850 nm), and activation of factor V by thrombin. Peptides HC3, HC4, and DYDYQ were also found to interact with immobilized thrombin. A recombinant factor V molecule with the mutations Asp(695) --> Lys, Tyr(696) --> Phe, Asp(697) --> Lys, and Tyr(698) --> Phe (factor V(2K2F)) was partially resistant to activation by thrombin but could be readily activated by RVV-V activator (factor Va(RVV)(2K2F)) and factor Xa (factor Va(Xa)(2K2F)). Factor Va(RVV)(2K2F) and factor Va(Xa)(2K2F) had impaired cofactor activity within prothrombinase in a system using purified reagents. Our data demonstrate for the first time that amino acid sequence 695-698 of factor Va heavy chain is important for procofactor activation and is required for optimum prothrombinase function. These data provide functional evidence for an essential and productive contribution of factor Va to the activity of prothrombinase.     

Intron-exon organization of the human gene coding for the lipoprotein-associated coagulation inhibitor: the factor Xa dependent inhibitor of the extrinsic pathway of coagulation

Blood coagulation can be initiated when factor VII(a) binds to its cofactor tissue factor. This factor VIIa/tissue factor complex proteolytically activates factors IX and X, which eventually leads to the formation of a fibrin clot. Plasma contains a lipoprotein-associated coagulation inhibitor (LACI) which inhibits factor Xa directly and, in a Xa-dependent manner, also inhibits the factor VIIa/tissue factor complex. Here we report the cloning of the human LACI gene and the elucidation of its intron-exon organization. The LACI gene, which spans about 70 kb, consists of nine exons separated by eight introns. As has been found for other Kunitz-type protease inhibitors, the domain structure of human LACI is reflected in the intron-exon organization of the gene. The 5' terminus of the LACI mRNA has been determined by primer extension and S1 nuclease mapping. The putative promoter was examined and found to contain two consensus sequences for AP-1 binding and one for NF-1 binding, but no TATA consensus promoter element.     

Tissue factor (coagulation factor III) inhibition by apolipoprotein A-II

Apolipoprotein A-II (apoA-II) has been shown to inhibit tissue factor participation in the activation of coagulation factor X by factor VIIa. The magnitude of inhibition was dependent on the concentration of the enzyme (factor VIIa) and substrate (factor X) present in the reaction. With factor VIIa at 0.86 nM, 0.41 microM apoA-II inhibited factor X activation as much as 50% at 200 nM factor X, with inhibition decreasing to 39% at 3 nM factor X. When factor X was held constant at 100 nM, 0.41 microM apoA-II inhibited its activation by 80% when factor VIIa was present at 26.7 pM, but the inhibition decreased to 47% when factor VIIa was increased to 1.75 nM. Kinetically, increasing apoA-II decreased the reaction Vmax. ApoA-II produced little effect on the apparent Km, but the apparent K1/2 for factor VIIa in the reaction increased as apoA-II concentration increased. In the presence of 0.75 pM bovine tissue factor, reconstituted with 4.31 microM phosphatidylserine-phosphatidylcholine (30:70, w/w) vesicles, and in the absence of apoA-II, the apparent Km was near 7 nM factor X when factor VIIa was present at 0.86 nM. Under the same conditions with factor X at 100 nM, the apparent K1/2 was near 56 pM factor VIIa. As apoA-II was added to 0.41 microM, the apparent K1/2 increased to about 200 pM factor VIIa. The aggregate results support a model in which apoA-II inhibits tissue factor potentiation of factor VIIa activity. Because the apparent K1/2 increases when apoA-II is added, the factor VIIa can apparently protect tissue factor from the effects of apoA-II. Thus, apoA-II appears to inhibit factor X activation by preventing the appropriate association of tissue factor with factor VIIa.